Thermolysin, reaction with active site

Similar reaction mechanisms, involving general base and metal ion catalysis, in conjunction with an OH nucleophilic attack, have been proposed for thermolysin (Ref. 12) and carboxypeptidase A (Refs. 12 and 13). Both these enzymes use Zn2+ as their catalytic metal and they also have additional positively charged active site residues (His 231 in thermolysin and... 

The N-hydroxy amino acid derivatives are likely to be applicable to other metalloproteases. Thermolysin is inhibited irreversibly at pH 7.2 by ClCH2CO-DL-HOLeu-OCH3 where HOLeu is N-hydroxyleucine (47). The inhibition reaction involves coordination of the hydroxamic acid functional group to the active-site zinc atom of the enzyme. This then places the chloroacetyl group adjacent to Glu-143, an essential catalytic residue of thermolysin (see Figure 9). An ester linkage is formed and the enzyme is inactivated irreversibly. This reagent also inactivated two neutral metalloproteases from B. subtilis, but reacted only very slowly with carboxypeptidase A (t1/2 > 3 d). 

Figure 9. Reaction of ClCH2CO-HOLeu-OMe with the active site of thermolysin (HOLeu is N-hydroxyleucine).

As was mentioned earlier, by far the largest number of zinc enzymes are involved in hydrolytic reactions, frequently associated with peptide bond cleavage. These include both exopeptidases, like carboxypeptidases A and B, which remove amino acids from the carboxyl-terminus of proteins, albeit with different specificities, and endopeptidases, like thermolysin, which cleave peptide bonds in the interior of the polypeptide chain. They have almost identical active sites (Figure 12.5) with two His and one Glu ligands to the Zn +. It appears that the Glu residue can be bound either in a mono- or bidentate manner. The two classes of enzymes are expected to follow similar reaction mechanisms. 

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